Retrieving hidden digital identifier

ABSTRACT

A method of providing access to securely held data is provided. A user interacts with the service provider to obtain access to a service by using a device to provide a digital identifier to the service provider, without the digital identifier being made known to the user. At a later date the user wishes to retrieve securely stored data relating to their use of the service. However, because the user does not know the digital identifier, they are unable to identify themselves to the service provider using the digital identifier. The present disclosure provides a secure method for exchanging private identifiers, which allows the user to identify themselves to the service provider in order to gain access to securely stored data relating to the user&#39;s previous use of the service. The user can do this using the device on which the digital identifier is stored, or another device.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No.16/665,768 filed on Oct. 28, 2019, which claims the benefit of, andpriority to, European Patent Application No. 18204089.9 filed on Nov. 2,2018. The entire disclosure of each of the above applications isincorporated herein by reference.

FIELD

The present disclosure relates to a method and a system for providingaccess to securely stored data.

BACKGROUND

This section provides background information related to the presentdisclosure which is not necessarily prior art.

In computer implemented communication and data exchange processes, it iscommon for users and devices to identify themselves to other users anddevices using digital identifiers. A digital identifier can be used toidentify a user or device that has permission to access secure systemsor data that are not open to the public. Similarly, digital identifierscan be used to identify users or devices that have permission to editdata held in secure systems. A device attempting to edit a database may,for example, be required to present a digital identifier before itsproposed changes to the database are permitted.

Due to the potentially sensitive permissions granted by digitalidentifiers, it is important that the digital identifiers can be storedand transmitted securely without being obtained by malicious thirdparties. In certain systems, a digital identifier can be stored within adevice and presented to outside systems without the identifier beingknown by the user of the device. For example, such an identifier may betransmitted in a near field communication (NFC) message. Though the userof the device may use the digital identifier to access outside systemsand data, the process does not involve providing the digital identifierto the user. Security risks associated with the provision of the digitalidentifier to the user, such as a malicious third party nearby readingthe identifier from a device screen over the user's shoulder, arethereby avoided.

While the direct transmission of a digital identifier stored on a deviceto an outside system without involving provision of the digitalidentifier to the device's user provides increased security, this doesmean that the user is unable to identify themselves to the outsidesystem when the electronic device is not in communication with it.

There is a need, therefore, for a method of providing a user with accessto securely stored data, in a system where access to the data is grantedin response to receipt of a digital identifier securely stored on adevice, without the digital identifier being made known to the device'suser.

SUMMARY

This section provides a general summary of the disclosure, and is not acomprehensive disclosure of its full scope or all of its features.Aspects and embodiments of the disclosure are set out in theaccompanying claims.

According to a first aspect, there is provided a computer implementedmethod of providing access to securely stored data, the methodcomprising a server of a service provider: receiving, from a userdevice, one or more requests for services, each such request indicatingthe same digital identifier; securely storing, in an interactionsdatabase, a record of each requested service together with the digitalidentifier; at a later time, receiving, from a communications device, arequest for a list of services provided to the user by the serviceprovider, said request indicating user details which are available tothe user but which were not indicated in any of the one or more requestsfor services; generating a special personal identifier number, ‘sPIN’,the sPIN indicating the user details and comprising a flag indicatingthat the sPIN indicates the user details; sending a request for thedigital identifier to the network processor, the request comprising thesPIN; receiving, from the network processor, a response to the requestfor the digital identifier, said response comprising the sPIN and thedigital identifier; responsive thereto, obtaining, from the interactionsdatabase, the record of each requested service associated with thedigital identifier; and providing, to the communications device, therecord of each requested service associated with the digital identifier.

The communications device can be the user device.

The digital identifier can be stored on the user device.

The digital identifier can be a payment token.

The sPIN can be in a format corresponding to that of a primary accountnumber (PAN).

The sPIN can consist of nineteen digits.

The user details can indicate one or both of an account number and asort code of an account associated with the digital identifier.

The flag can be a single digit.

The first six digits of the sPIN can identify an issuer of the account,and indicate the first two digits of the sort code; one of the remainingdigits of the sPIN can be the flag; eight of the remaining digits of thesPIN can indicate the account number; and four of the remaining digitsof the sPIN can indicate the last four digits of the sort code.

The flag can be a flag code corresponding to a code stored by thenetwork processor and/or an issuer of an account associated with thedigital identifier.

The first six digits of the sPIN can be the flag code, and identify anissuer of the account; one of the remaining digits of the sPIN canindicates the first two digits of the sort code; eight of the remainingdigits of the sPIN can indicate the account number; and four of theremaining digits of the sPIN can indicate the last four digits of thesort code.

The first six digits of the sPIN can be the flag code, and identify anissuer of the account; the final digit of the flag code can indicate adigit of the sort code; five of the remaining digits of the sPIN canindicate the remainder of the sort code; and eight of the remainingdigits of the sPIN can indicate the account number.

The method can further comprise, prior to receiving the request for thelist of services provided to the user by the service provider:receiving, from a further user device, one or more further requests forservices, each such request indicating a further digital identifierdifferent to the digital identifier referred to above; and securelystoring, in the interactions database, a record of each furtherrequested service together with the further digital identifier; whereinthe response to the request for the digital identifier further comprisesthe further digital identifier. The method can further comprise:responsive to receiving the response, obtaining, from the interactionsdatabase, the record of each further requested service associated withthe further digital identifier; and providing, to the communicationsdevice, the record of each further requested service associated with thefurther digital identifier.

According to a second aspect there is provided a computer systemconfigured to perform the method of the first aspect.

According to a third aspect there is provided a computer readable mediumcomprising instructions which, when executed by a processor, cause themethod of the first aspect to be performed.

Further areas of applicability will become apparent from the descriptionprovided herein. The description and specific examples in this summaryare intended for purposes of illustration only and are not intended tolimit the scope of the present disclosure.

DRAWINGS

The drawings described herein are for illustrative purposes only ofselected embodiments and not all possible implementations, and are notintended to limit the scope of the present disclosure. In connectiontherewith, aspects of the present disclosure will now be described byway of example with reference to the accompanying figures. In thefigures:

FIG. 1 illustrates an example system in which the methods describedherein can be used;

FIG. 2 illustrates an example of a previous interaction database;

FIG. 3 illustrates an example method of payment;

FIG. 4 illustrates an example method of exchanging identification datathat allows a user to identify themselves to a service provider in orderto access data relating to previous interactions between the user andthe service provider;

FIG. 5 illustrates an example sPIN;

FIG. 6 illustrates a further example sPIN;

FIG. 7 illustrates yet another example sPIN; and

FIG. 8 is a flowchart of an example method.

Corresponding reference numerals indicate corresponding parts throughoutthe several views of the drawings.

DETAILED DESCRIPTION

Embodiments will be described, by way of example only, with reference tothe drawings. The description and specific examples included herein areintended for purposes of illustration only and are not intended to limitthe scope of the present disclosure. The following description ispresented to enable any person skilled in the art to make and use thesystem, and is provided in the context of a particular application.Various modifications to the disclosed embodiments will be readilyapparent to those skilled in the art.

In the following, references to entities, such as service providers(including transit providers), acquirers, network processors andissuers, should be understood to refer to servers operated by thoseentities. For example, a message described as being forwarded from anacquirer to an issuer via a network processor is sent from theacquirer's server, to the network processor's server then on to theissuer's server.

The present disclosure provides a method of providing access to dataheld securely by a service provider. A user interacts with the serviceprovider to obtain access to a service by using a device to provide adigital identifier to the service provider, without the digitalidentifier being made known to the user. At a later date the user wishesto retrieve securely stored data relating to their use of the service.However, because the user does not know the digital identifier, they areunable to identify themselves to the service provider using the digitalidentifier. The present disclosure provides a secure method forexchanging private identifiers, which allows the user to identifythemselves to the service provider in order to gain access to securelystored data relating to the user's previous use of the service. The usercan do this using the device on which the digital identifier is stored,or another device.

The method is illustrated below in the context of a transit system. Itwill be understood, however, that the principles discussed herein areapplicable to a range of systems that require secure exchanges of data.

FIG. 1 illustrates part of a system suitable for use in the presentmethod and demonstrates how elements of the system interact to securelygenerate, store and transmit data.

In particular, the below disclosure illustrates how the method can beused to allow a set of tokenized credentials to be used in a transitnetwork configured to operate in accordance with a message exchangeprotocol in which an authorization response is provided to a serviceprovider.

The system comprises a service provider 100 that is configured tointeract with a user 203 such that at least part of the interaction isautomated. For example, this may be through the user 203 tapping anentry device, such as a tokenized mobile payment device 200, onto adedicated reader, for example, on an entry gate, e.g., in order to gainaccess to a transit network. In this example, the service provider 100is a transit provider, such as a rail and/or bus network operator.However, the method described below is applicable to a number ofdifferent systems. For example, the service provider could be agymnasium, sports or entertainment venue or hotel room that requiresidentification upon entry, or a vending machine that accepts digitalpayments.

The service provider 100 comprises several elements that may be at thesame location, or disposed in separate locations, including a server101, a communication node 102 and a database 103, which can interactwith each other as and when required. Processes described below that areperformed by the service provider 100 should be understood as beingcontrolled by the service provider server 101.

A user 203 interacts with the service provider 100 using a device 200configured for interaction with the service provider 100. The device 200stores a digital identifier 211 in a storage element 210. The storageelement 210 could, for example, be a local storage element of the device200, such as a secure element, a trusted execution environment or anarea of device memory used by host card emulation software, or could bea remote storage element which the device 200 can communicate securelywith, for example, as a means of cloud storage.

The device 200 is capable of transmitting the digital identifier 211 tothe service provider 100. In the present example, the digital identifier211 can be used to make payments from an account to which the user 203has access to the service provider 100. For example, the device 200 maybe a payment card comprising a radio frequency identification (RFID) tagor a mobile electronic device comprising a near field communication(NFC) element.

The digital identifier 211 allows the user to identify themselves to theservice provider. The digital identifier 211 may, for example, be apayment token that can be used by the service provider 100 to initiate apayment from the user 203 to the service provider 100, e.g., such thatthe user can be granted access to a transit network. In such an example,the payment token is linked to payment credentials that are known to theuser 203, such as an account number and sort code. In this example, theuser 203 has opted to tokenize their account details, which has resultedin a payment token being provisioned onto their device 200. Such paymenttokens can be provided to electronic point of sale terminals in asimilar way to the credentials stored on the chip of a plastic NFC card.Each payment token contains a set of card-like credentials that areunknown to the user 203 (i.e., the user 203 knows their account details,but not the token details).

The service provider 100 comprises a previous interaction database 103that stores records of interactions between the user 203 and the serviceprovider 100. The previous interaction database 103 may be disposed in asingle location or distributed across multiple locations. In the transitexample, such previous interactions databases 103 may be used, forexample, for the purposes of fare calculation in order that the user 203may be charged the correct fare(s) for their journey(s) by billing thecredentials 221 used to access the service provider 100.

The user 203 provides the digital identifier 211 to the service provider100 when accessing services provided by the service provider 100. In thepresent example, when a user 203 attempts to access the transit network,the user 203 presents the digital identifier 211 to the service provider100 by transmitting the digital identifier 211 from a communication node202 of the device 200 to a communication node 102 of the serviceprovider 100. For example, the communication node 202 of the device 200may be an RFID tag or an NFC element and the communication node 102 ofthe service provider 100 may respectively be an RFID reader or an NFCreader. For example, the digital identifier 211 may be passed as part ofa contactless EMV transaction.

If the service provider 100 accepts the digital identifier 211, the user203 is allowed access to the transit network. For example, access to atrain boarding area may be provided by opening a physical barrier. Thecommunication node 102 of the service provider 100 could, for example,be located on such a barrier or gate. The service provider 100 mayrequire that certain conditions are met before the user is providedaccess to the service: for example, the service provider 100 may checkthat the digital identifier 211 does not belong to a user that is bannedfrom entering the system, or the service provider 100 may check that thedigital identifier 211 can be validly used to initiate a payment to theservice provider 100.

After providing the user 203 with access to the transit service, theservice provider 100 creates a data entry 113 in a previous interactiondatabase 103, for example, as illustrated in FIG. 2 . In some examples,the data entry 113 may be generated immediately upon providing access tothe user 203. In other examples, the data entry may be generated whenthe user 203 has finished using the service, or later, e.g., as part ofa consolidated data batch for a predefined period of time, such as a dayor a week. FIG. 2 shows an example of a previous interaction database103 comprising a plurality of data entries 113, each corresponding to aprevious interaction between a user and a transit network. Each dataentry record 113 comprises a digital identifier 211 and otherinformation regarding the interaction. For example, the data entry 113may comprise data indicating the time of initiation of the service (forexample, the time the user 203 enters a train boarding area at anoriginating station), the time of completion of the service (forexample, the time the user 203 exits a train boarding area at adestination station), a corresponding transaction amount, a startlocation and an end location.

The service provider 100 uses the digital identifier 211 to initiate apayment from the user 203 to the service provider 100, as illustrated byFIG. 3 . To initiate the payment, the service provider 100 provides thedigital identifier 211 and an indication of a payment amount to anacquiring financial institution (acquirer) 300 associated with theservice provider 100. The acquiring financial institution 300 sends apayment request message to a network processor 400 for forwarding to anissuing financial institution (issuer) 500 associated with the user 203.The network processor 400 may form part of a payment processing networkand may incorporate parts of several interlinked payment processingnetworks.

The payment may be initiated upon access to the service provider 100being granted to the user 203, or the payment may be initiated after theuser 203 has finished using the transit service.

Alternatively, an authorization to commence a period of aggregation mayoccur soon after the user's entry to the transit network. In thisexample, the user 203 enters the transit network, providing theirdigital identifier 211 which is not on a list deemed unacceptable. Thedigital identifier 211, along with the date, time and location of entryis sent to the service provider server 101. The service provider server101 determines whether the digital identifier 211 has recently had agood authorization. If not, a new authorization request is initiated bysending a message to the acquirer 300, then on to the network processor400, and finally to the issuer 500. If the issuer 500 approves theauthorization request, then the service provider 100 starts to collectentry/exit taps representing journeys up to a value agreed with eitherthe issuer 500, network processor 400, or acquirer 300, in order tomanage liability. Once that value limit is reached, the service provider100 takes the necessary steps to clear and settle for the journeysconsumed by the user 203.

If the authorization request is declined by the issuer 500, then thedigital identifier 211 is added to a list to prevent further consumptionof travel against that identifier 211. The user 203 and/or the serviceprovider 100 takes steps to recover any monies owed before removing theidentifier 211 from the aforementioned list.

Whatever the timing and specific process used for authorization of apayment, at some point the digital identifier 211 must be translatedinto corresponding payment credentials 221 of a payment account. Thiscan, for example, be done by the network processor 400 or the issuer500.

In an example where the network processor 400 converts the digitalidentifier 211 to payment credentials 221, the network processor 400may, for example, have access to a token database 410 comprising dataindicating which payment credentials 221 are associated with givenpayment tokens. Alternatively, the network processor 400 may operate onthe payment token according to a pre-determined algorithm in order toobtain the payment credentials 221.

In this example, the network processor 400 sends a payment requestmessage to the issuing institution 500 associated with the user 203,where the payment request message comprises the payment credentials 221associated with the user 203. The issuer 500 processes the request andsends the response back to the network processor 400. The networkprocessor 400 then returns the issuer response to the acquirer 300,which in turn relays it to the service provider 100. The response to thetransit operator 100 typically comprises information about whether thetransaction was approved or declined.

The payment process may, for example, be an ISO 8583 0100 authorizationrequest, a 20022 authorization request, a Faster Payment message oranother kind of payment transaction.

After an interaction as described above, the relevant parties haveaccess to the following information.

The user is aware of their payment credentials 221 (because the user hadaccess to the payment credentials to begin with) but has not beenprovided with the digital identifier 211.

The service provider 100 has access to the digital identifier 211 (whichwas provided by the device 200 when the user 203 accessed the transitnetwork) and to information relating to the interaction between the user203 and the transit network. This information is stored in the previousinteraction database 103. The service provider 100 has not been providedwith the user's payment credentials 221.

The network processor 400 and/or issuer 500 have access to the user'sdigital identifier 211 and linked payment credentials 221 (as, forexample, retrieved from a tokenization database 410 or obtained using apre-determined algorithm), but do not have access to details of theuser's interactions with the service provider 100.

The service provider 100 provides a service, e.g., an internet ortelephone based service, that allows users 203 to access details ofprevious interactions. Users 203 may access this service through acommunication device 220, as shown in FIG. 4 . The communication device220 may, for example, be a desktop computer, laptop computer, a mobileelectronic device, such as a tablet or smartphone, a telephone, aterminal operated by the service provider 100 (e.g., a self-serviceticket machine). The communication device 220 may, in some examples, bethe same device as the device 200 used to provide the digital identifier211 to the service provider 100. The communication device may, forexample, provide access to the service through a web browser or anapplication.

In order to access details of previous interactions, the user 203 mustidentify themselves to the service provider 100. This allows the serviceprovider 100 to obtain previous interaction data associated with thecorrect user and to ensure that private data is not being shared withunauthorised parties.

In the present scenario, where the service provider 100 is not providedwith payment credentials known to the user 203 in response to a paymentrequest (but is only provided with a digital identifier 211), it is notpossible for the user 203 to identify themselves to the service provider100 to obtain the desired information.

The following steps, illustrated by FIG. 4 , provide a method ofexchanging identification data that allows a user to identify themselvesto a service provider 100 in order to access data relating to previousinteractions between the user 203 and the service provider 100.

The user 203 uses a communication device 220 to provide user details tothe service provider 100, e.g., via a user interface. The user detailsmay be, for example, an account number and sort code or an IBAN that maybe manually typed into text boxes provided in a web browser or mobileapplication. Data corresponding to user details and a request for a listof previous services provided to the user 203 by the service provider100 are sent from the communication device 220 to the service provider100.

The service provider 100 then generates a special personal identifiernumber, ‘sPIN’, based on the user details. The sPIN comprises the datacorresponding to the user details and a flag indicating to the networkprocessor that the sPIN contains the user details. The sPIN may, forexample, have the same number format as payment credentials for use in afour party card authorization process.

A request comprising the sPIN is then sent from the service provider 100to the network processor 400, via the acquirer 300. The request may, forexample, appear to the network processor 400 as an account statusenquiry request. The request may, for example, be an ISO 8535 0100request message.

The network processor 400 and the issuing institution 500 process therequest and perform any necessary checks, including security checks. Thenetwork processor 400 determines from the flag that the sPIN containsthe user details. The network processor 400 extracts the user detailsfrom the sPIN and uses the user details to obtain one or more digitalidentifiers 211 linked to the user details. (More than one digitalidentifier may be linked to a single set of user details if those userdetails have been digitized multiple times. For example, a single bankaccount could be digitized onto both a smartphone and a smartwatch, orinto multiple digital wallets on the same device.) This is the reverseof the process described above during a payment request in which thenetwork processor 400 uses the digital identifier 211 to obtain userdetails. Alternatively, the network processor 400 can route the requestto the issuer 500, which then recognizes the flag and takes on theresponsibility for the conversion.

The network processor 400 sends a response to the service provider 100(via the acquirer 300), the response comprising the sPIN and datacorresponding to the one or more digital identifiers 211. As a result ofthe response, the service provider 100 now has access to both thedigital identifier(s) 211 (that is generally unknown by the user 203)and the user details that are known by the user 203. The serviceprovider 100 may then edit the entries in the previous interactiondatabase 103 to include the user details in all data entries that areassociated with the digital identifier(s) 211.

The service provider 100 then obtains a list of previous interactionsbetween the user 203 and the service provider 100. In order to obtainthe list of previous interactions, the service provider 100 searches theprevious interaction database 103 for data entries comprising thedigital identifier(s) 211.

Finally, the service provider 100 provides to the user 203 a messagecomprising the list of previous interactions associated with the digitalidentifier(s) 211. The message may be provided to a communication device220 of the user 203, and may, for example, be displayed to the user 203using a display screen of the communication device 220.

The above method allows the user 203 to identify themselves to theservice provider (e.g., transit provider) while using pre-existing dataexchange processes of a four party card payment authorization system.

FIG. 5 shows an example of an sPIN 700 that may be processed withinexisting payment processing systems. The sPIN comprises nineteen digits(which is typically the maximum length allowed for the PAN field in ISO8583 messages) which may be treated by an issuing 500 or acquiring 300institution as though it were a normal credit card or debit card paymentnumber. In the example of FIG. 5 , the first six digits 702 of the sPIN700 correspond to the bank identification number (BIN) that allows thenetwork processor 400 to identify the issuing institution 500 to whichthe request message comprising the sPIN 700 should be forwarded. Theseventh digit 701 is a flag which indicates to the network processor 400that the sPIN 700 comprises user details. The eighth to fifteenth digits703 indicate the account number of the user 203 and the sixteenth tonineteenth digits 704 indicate the last four digits of the sort code ofthe corresponding account. Since existing payment processing conventionsrequire that a one-to-one mapping exists between the BIN of a user'sissuing institution and the first two digits of a user's sort code, thenetwork processor 400 is able to determine the initial two digits of thesort code using the BIN by referring to a lookup table. The eighth tothe nineteenth digits together correspond to the user details whencombined with the first two digits of the sort code as determined fromthe BIN.

FIG. 6 shows an alternative example on a nineteen digit sPIN 800.Similarly to the example of FIG. 5 , the first six digits 802 are theBIN, the eighth to fifteenth digits 803 are the account number and thesixteenth to nineteenth digits 804 are the last four digits of the sortcode. However, in this case the BIN in a dedicated flag BIN, which thenetwork processor 400 or the issuer 500 can identify in a look-up table.In this example, the seventh digit 801 indicates the first two digits ofthe sort code.

FIG. 7 shows a further alternative example of an sPIN 900. Similarly tothe example of FIG. 6 , the BIN in this case is a dedicated flag BIN. Inthis example, the BIN 902 and sort codes 904 are chosen in advance suchthat the last digit of the BIN 902 is the same as the first digit of thesort code 904. Thus, the six digit BIN 902, the six digit sort code 904,and the eight digit account number 903 can be included in a nineteendigit sPIN 900 by using a single digit to represent both the final digitof the BIN and the first digit of the sort code.

For sPINs to be processed, it may be necessary to turn off certainsecurity and/or data integrity checks (such as, Luhn check digitvalidation) usually implemented by a network processor 400.

FIG. 8 is a flowchart illustrating the steps of an example methodperformed by a server of a service provider, such as transit providerserver 101.

At step S1 the service provider receives, from a user device, a requestfor a service, the request indicating a digital identifier. At step S2the service provider securely stores, in an interactions database, arecord of the requested service together with the digital identifier.These steps may optionally be repeated one or more times if multipleservices are requested using the same digital identifier.

At a later time, at step S3 the service provider server receives from acommunications device a request for a list of services provided to theuser by the service provider, said request indicating user details whichare available to the user but which were not indicated in any of the oneor more requests for services.

The service provider server then generates a special personal identifiernumber (sPIN) at step S4, the sPIN indicating the user details andcomprising a flag indicating to a network processor that the sPINindicates the user details. At step S5 the service provider server sendsa request for the digital identifier to the network processor, therequest comprising the sPIN.

At step S6, the service provider server receives, from the networkprocessor, a response to the request for the digital identifier, saidresponse comprising the sPIN and the digital identifier. In response tothis, at step S7 the service provider server obtains, from theinteractions database, the record of each requested service associatedwith the digital identifier. Finally, at step S8 the service providerserver provides, to the communications device, the record of eachrequested service associated with the digital identifier.

Other embodiments will be apparent to those skilled in the art fromconsideration of the specification and practice of the embodimentsdisclosed herein. It is intended that the specification and examples beconsidered as exemplary only.

In addition, where this application has listed the steps of a method orprocedure in a specific order, it could be possible, or even expedientin certain circumstances, to change the order in which some steps areperformed, and it is intended that the particular steps of the method orprocedure claims set forth herein not be construed as beingorder-specific unless such order specificity is expressly stated in theclaim. That is, the operations/steps may be performed in any order,unless otherwise specified, and embodiments may include additional orfewer operations/steps than those disclosed herein. It is furthercontemplated that executing or performing a particular operation/stepbefore, contemporaneously with, or after another operation is inaccordance with the described embodiments.

The methods described herein may be encoded as executable instructionsembodied in a computer readable medium, including, without limitation,non-transitory computer-readable storage, a storage device, and/or amemory device. Such instructions, when executed by a processor (or oneor more computers, processors, and/or other devices) cause the processor(the one or more computers, processors, and/or other devices) to performat least a portion of the methods described herein. A non-transitorycomputer-readable storage medium includes, but is not limited to,volatile memory, non-volatile memory, magnetic and optical storagedevices such as disk drives, magnetic tape, CDs (compact discs), DVDs(digital versatile discs), or other media that are capable of storingcode and/or data.

The methods and processes can also be partially or fully embodied inhardware modules or apparatuses or firmware, so that when the hardwaremodules or apparatuses are activated, they perform the associatedmethods and processes. The methods and processes can be embodied using acombination of code, data, and hardware modules or apparatuses.

Examples of processing systems, environments, and/or configurations thatmay be suitable for use with the embodiments described herein include,but are not limited to, embedded computer devices, personal computers,server computers (specific or cloud (virtual) servers), hand-held orlaptop devices, multiprocessor systems, microprocessor-based systems,set top boxes, programmable consumer electronics, mobile telephones,network PCs, minicomputers, mainframe computers, distributed computingenvironments that include any of the above systems or devices, and thelike. Hardware modules or apparatuses described in this disclosureinclude, but are not limited to, application-specific integratedcircuits (ASICs), field-programmable gate arrays (FPGAs), dedicated orshared processors, and/or other hardware modules or apparatuses.

Receivers and transmitters as described herein may be standalone or maybe comprised in transceivers. User input devices can include, withoutlimitation, microphones, buttons, keypads, touchscreens, touchpads,trackballs, joysticks and mice. User output devices can include, withoutlimitation, speakers, graphical user interfaces, indicator lights andrefreshable braille displays. User interface devices can comprise one ormore user input devices, one or more user output devices, or both.

With that said, and as described, it should be appreciated that one ormore aspects of the present disclosure transform a general-purposecomputing device into a special-purpose computing device (or computer)when configured to perform the functions, methods, and/or processesdescribed herein. In connection therewith, in various embodiments,computer-executable instructions (or code) may be stored in memory ofsuch computing device for execution by a processor to cause theprocessor to perform one or more of the functions, methods, and/orprocesses described herein, such that the memory is a physical,tangible, and non-transitory computer readable storage media. Suchinstructions often improve the efficiencies and/or performance of theprocessor that is performing one or more of the various operationsherein. It should be appreciated that the memory may include a varietyof different memories, each implemented in one or more of the operationsor processes described herein. What's more, a computing device as usedherein may include a single computing device or multiple computingdevices.

In addition, and as described, the terminology used herein is for thepurpose of describing particular exemplary embodiments only and is notintended to be limiting. As used herein, the singular forms “a,” “an,”and “the” may be intended to include the plural forms as well, unlessthe context clearly indicates otherwise. And, again, the terms“comprises,” “comprising,” “including,” and “having,” are inclusive andtherefore specify the presence of stated features, integers, steps,operations, elements, and/or components, but do not preclude thepresence or addition of one or more other features, integers, steps,operations, elements, components, and/or groups thereof. The methodsteps, processes, and operations described herein are not to beconstrued as necessarily requiring their performance in the particularorder discussed or illustrated, unless specifically identified as anorder of performance. It is also to be understood that additional oralternative steps may be employed.

When a feature is referred to as being “on,” “engaged to,” “connectedto,” “coupled to,” “associated with,” “included with,” or “incommunication with” another feature, it may be directly on, engaged,connected, coupled, associated, included, or in communication to or withthe other feature, or intervening features may be present. As usedherein, the term “and/or” and the term “at least one of” includes anyand all combinations of one or more of the associated listed items.

Although the terms first, second, third, etc. may be used herein todescribe various features, these features should not be limited by theseterms. These terms may be only used to distinguish one feature fromanother. Terms such as “first,” “second,” and other numerical terms whenused herein do not imply a sequence or order unless clearly indicated bythe context. Thus, a first feature discussed herein could be termed asecond feature without departing from the teachings of the exampleembodiments.

It is also noted that none of the elements recited in the claims hereinare intended to be a means-plus-function element within the meaning of35 U.S.C. § 112(f) unless an element is expressly recited using thephrase “means for,” or in the case of a method claim using the phrases“operation for” or “step for.”

Again, the foregoing description of exemplary embodiments has beenprovided for purposes of illustration and description. It is notintended to be exhaustive or to limit the disclosure. Individualelements or features of a particular embodiment are generally notlimited to that particular embodiment, but, where applicable, areinterchangeable and can be used in a selected embodiment, even if notspecifically shown or described. The same may also be varied in manyways. Such variations are not to be regarded as a departure from thedisclosure, and all such modifications are intended to be includedwithin the scope of the disclosure.

What is claimed is:
 1. A computer implemented method of providing accessto securely stored data, the method comprising: receiving, at a server,from a communications device, a list request for a list of servicesprovided to a user by a service provider, said list request indicatinguser details, which are available to the user, but which were notindicated in service requests for the services, the user detailsincluding an account number of an account associated with a digitalidentifier, the account number different than the digital identifier;generating, by the server, a special personal identifier number (sPIN),the sPIN indicating the user details, the sPIN different than theaccount number and the digital identifier; sending, by the server, anidentifier request for the digital identifier to a network processor,the identifier request including the sPIN; receiving, at the server,from the network processor, a response to the identifier request for thedigital identifier, said response including the digital identifier;responsive thereto, obtaining, by the server, from an interactionsdatabase, multiple records associated with the services, a record ofeach of the services associated with the digital identifier; andproviding, by the server, to the communications device, the record ofeach of the services associated with the digital identifier, in responseto the list request.
 2. The method of claim 1, wherein thecommunications device includes a user device; and wherein the servicesinclude a transit service.
 3. The method of claim 2, wherein the digitalidentifier is stored in a secure element (SE) of the user device; andwherein the digital identifier is a payment token.
 4. The method ofclaim 1, further comprising securely storing, by the server, themultiple records in the interaction database in association with thedigital identifier.
 5. The method of claim 1, wherein the sPIN includesa format consistent with that of a primary account number (PAN).
 6. Themethod of claim 1, wherein the user details further include a sort codeof the account associated with the digital identifier, the sort codeindicative of at least an issuer of the account associated with thedigital identifier.
 7. The method of claim 1, wherein the response, fromthe network processor, includes the sPIN.
 8. The method of claim 1,wherein the sPIN includes a flag, which indicates to the networkprocessor that the sPIN indicates the user details; and wherein the flagincludes a single digit.
 9. The method of claim 8, wherein: the sPINincludes a format consistent with that of a primary account number (PAN)for the account associated with the digital identifier; the user detailsindicate one or both of the primary account number and a sort code ofthe account; a first six digits of the sPIN indicate an issuer of theaccount and a first two digits of the sort code; one of the remainingdigits of the sPIN is the flag; eight of the remaining digits of thesPIN indicate an account number specific to the account; and four of theremaining digits of the sPIN indicate a last four digits of the sortcode.
 10. The method of claim 1, wherein the sPIN includes a flag codecorresponding to a code stored by the network processor and/or an issuerof the account associated with the digital identifier.
 11. The method ofclaim 10, wherein the sPIN consists of nineteen digits.
 12. The methodof claim 10, wherein: the sPIN is in a format corresponding to that of aprimary account number (PAN) for the account associated with the digitalidentifier; the user details indicate a sort code of the account; afirst six digits of the sPIN are the flag code, and identify an issuerof the account; one of the remaining digits of the sPIN indicates afirst two digits of the sort code; eight of the remaining digits of thesPIN indicate an account number of the account, which is included in thePAN; and four of the remaining digits of the sPIN include a last fourdigits of the sort code.
 13. The method of claim 10, wherein: the sPINis in a format corresponding to that of a primary account number (PAN)for the account associated with the digital identifier; the user detailsindicate a sort code of the account; a first six digits of the sPIN arethe flag code, and identify an issuer of the account; a final digit ofthe flag code indicates a digit of the sort code; five of the remainingdigits of the sPIN indicate a remainder of the sort code; and eight ofthe remaining digits of the sPIN include an account number of theaccount, which is included in the PAN.
 14. A server, associated with aservice provider, for use in providing access to securely stored data,the server comprising at least one computing device configured to:receive, from a communications device, a list request for a list ofservices provided to a user by a service provider, said list requestindicating user details, which are available to the user, but which werenot indicated in service requests for the services, the user detailsincluding an account number of an account associated with a digitalidentifier, the account number different than the digital identifier;generate a special personal identifier number (sPIN), the sPINindicating the user details, the sPIN different than the account numberand the digital identifier; send an identifier request for the digitalidentifier to a network processor, the identifier request including thesPIN; receive, from the network processor, a response to the identifierrequest for the digital identifier, said response including the sPIN andthe digital identifier; responsive thereto, obtain, from an interactionsdatabase, multiple records associated with the services, a record ofeach of the services associated with the digital identifier; andprovide, to the communications device, the record of each of theservices associated with the digital identifier, in response to the listrequest.
 15. The server of claim 14, wherein the services include atransit service; and wherein the communications device includes thedigital identifier in a secure element (SE) of the communicationsdevice.
 16. The server of claim 15, wherein the digital identifier is apayment token.
 17. The server of claim 14, wherein the sPIN includes aflag, which indicates to the network processor that the sPIN indicatesthe user details; and wherein the flag includes a single digit.
 18. Theserver of claim 17, wherein: the sPIN includes a format consistent withthat of a primary account number (PAN) for the account associated withthe digital identifier; the user details indicate one or both of theprimary account number and a sort code of the account; a first sixdigits of the sPIN indicating an issuer of the account and a first twodigits of the sort code; one of the remaining digits of the sPIN is theflag; eight of the remaining digits of the sPIN indicate an accountnumber specific to the account; and four of the remaining digits of thesPIN indicate a last four digits of the sort code.
 19. A non-transitorycomputer-readable storage medium comprising instructions for providingaccess to securely stored data, which, when executed by a processor,cause the processor to: receive, from a communications device, a listrequest for a list of services provided to a user by a service provider,said list request indicating user details, which are available to theuser, but which were not indicated in service requests for the services,the user details including an account number of an account associatedwith a digital identifier, the account number different than the digitalidentifier; generate a special personal identifier number (sPIN), thesPIN indicating the user details, the sPIN different than the accountnumber and the digital identifier; send an identifier request for thedigital identifier to a network processor, the identifier requestincluding the sPIN; receive, from the network processor, a response tothe identifier request for the digital identifier, said responseincluding the sPIN and the digital identifier; responsive thereto,obtain, from an interactions database, multiple records associated withthe services, a record of each of the services associated with thedigital identifier; and provide, to the communications device, therecord of each of the services associated with the digital identifier,in response to the list request.